Vol. 2, No. 3, May-June, 1963
CABBON DIOXIDE INCOBPOaATION I N T O UaACn
573
Carbon Dioxide lncorporation into the Uracil of Mouse Liver and Ehrlich Ascites Tumor Cells* KRIICHIKIJSAMA~ AND EUGENE ROBERTS From the uepartment of Binchemistry, City of Hope Mediad Cents; Duurte, California Received M a y 21, 1962
NaHCQ solution was injected intraperitoneally into mice bearing the Ehrlich ascites tumor, and uracil was isolated from the RNA of the ascites cells and from the acid-soluble fractions of both ascites cells and liver. The activity of the C-2 carbon of uracil was measured by a new micromethod usable down to 5 moles of uracil and was compared to the activity of the other carbon atoms. The percentage of total activity found in the C-2 of the uracil of the ascites cells (90%) was much greater than that in liver (50%). Although attempts to demonstrate the presence of carbamyl phosphate synthetase activity in preparations from the Ehrlich ascites cells were unsuccessful, the results are consistent with a primary h a t i o n of COe into carbamyl phosphate or some other carbamyl donor which participates subsequently in pyrimidine biosynthesis in these cells. It is possible that in the tumors some compound other than carbamyl phosphate is the carbamyl donor or that the carbamyl phosphate used in vivo for the synthesis of uracil may be formed in some other tissue, possibly the liver, and then made available to the tumor cells for biosynthetic purposes. assayed in a Tricarb Liquid Scintillation Spectrometer (Model 314 X) for several periods of 10 minutes each are very active in these cells in comparison with other at -8”. In the case of C02, the gas was liberated by tissues (Calva et d . , 1959; Reichard and Skold, 1957; acidification and absorbed directly by 1ml of Hyamine Skold, 1960). At the time this work was initiated solution in an apparatus Rimilnr to that described by there were no reports of the detection of carbamyl Siskenetal. (1961). phosphate synthetase activity, the first step of pyrimiPrepamtion of RNA HydroZysate.-In each experidine biosynthesis, in cancer cells. We attempted to ment, two mice were injected intraperitoneally with measure the activity of this enzyme in Ehrlich cells 0.5 ml of NaHCIQ solution containing either 5 pc by methods previously applied to liver and intestine or 25 pc (solution prepared from original material (Hall et al., 1960), but failed to detect any activity in of approximately 10 mc/mmole obtained from Califorvarious types of extracts of these cells. During the nia Corporation for Biochemical Research) and the course of this work it was reported that neither carmice were sacrificed 5 minutes, 15 minutes, or 1, 3, 6, bamyl phosphate synthetase nor ornithine transor 24 hours after injection. Ascites fluid was drained carbamylase activities could be detected in Ehrlich from the mice and the cells were collected by Centrifugaascites tumor cells but that high levels of aspartate tion, then twice washed with cold 0.85% NaCl solution. transcarbamylase were found (Jones et al., 1961). We An equal volume of 1 N perchloric acid was added to then changed to a study of the in vivo incorporation the tumor cells,the mixture was stirred and centrifuged, of CIQ into the C-2 position of the uracil of the ascites and the precipitate was washed twice with 0.3 N cell RNA and of the acid-soluble nucleotides of the perchloric acid. The supernatant fluids were comascites cells and the livers of the tumor-bearing animals bined as the “acid-soluble fraction.” The precipitate in order to get further insight into this problem. was u s d for the preparation of a KOH hydrolysate of Hitherto, approximately 200 pmoles of uracil has the cell RNA according to Tyner et al. (1953). The been required for the degradative procedures in the KOH solution was neutralized with perchloric acid estimation of radioactivity of the C-2 carbon of uracil and the KClO, centrifuged. The supernatant fluid (Heinrich and Wilson, 1950). In the present work was called the “RNA hydrolysate.” Livers were the procedure has been made more sensitive, so that removed from the same mice, after the ascites fluid the minimum amount required is about 5 pmoles. was drained, and homogenized with 1 N perchloric acid in a Waring Blendor. The homogenate was treated the same as the ascites cells and separated into EXPERIMENTAL the same two fractions. Animals.4wiss mice bearing 7- to lo-day-old In the in vitro experiments, 2 ml of Ehrlich ascites Ehrlich tumors were used for the experiments. fluid and cells (obtained 9 days after inoculation) conDetermination of Radioactivity.-Meed amounts taining a small amount of heparin was placed in a small of aqueous samples were pipetted into Tricarb vials flask and the mouth was closed tightly with a rubber and dried under a stream of warm air. One ml of 1 M stopper. Five-tenths ml NaHC’Q (25 pc) solution Hyamine 10-X in methanol’ and 15 ml of 100% toluene was injected through the rubber stopper. This flask counting solution were added.’ Radioactivity WES was incubated for 15 or 30 minutes at 37” and the * This investigation was supported in part by grant contents were poured into a centrifuge tube. Two C-2568 from the National Cancer Institute, National Instiml of 1 N perchloric acid was added and the precipitate tutes of Health, Bethesda, Maryland. was centrifuged. The procedure thereafter was the t Present address: Department of Biophysics and Eio- same as for the in vivo experiments. chemistry, Faculty of Science, University of Tokyo, Bunkyo, separation of Nucleotides fmm RNA Hydrolysate.Tokyo, Japan. 1 Hyamine 10-X is p(diisobuty1-cresoxyethoxyethy1)- The neutralized RNA hydrolysate again was made alkaline by addition of ammonium hydroxide solution dimethylbenzylammonium hydroxide. and run through a 1 X 5 c m column of Dowex 1 X8 lo00 ml of toluene contains 3.0 g of 2,5-diphenyloxazole (PPO) and 0.1 g of 1,4-bis-2-(5-phenyloxazolyl)- (formate form, 20(t400 mesh), followed by 50 ml of benzene (POPOP). water. CMP, AMP, and GMP were eluted separately Biosynthesis of RNA takes place rapidly in Ehrlich
ascites cells, and the enzymes related to RNA synthesis
574
KEIICHI KUSAMA AND EUGENE ROBERTS
by a modification of the method of Cohn and Volkin (1951). The solvents used were 0.02 M formic acid, 0.15 M formic acid, 0.01 M formic acid 0.075 Y ammonium formate, and 0.2 Y formic acid 0.2 Y ammonium formate. The effluent was collected in 10-ml fractions and the optical density of each fraction was determined at 260 mp with a Beckman Model DU spectrophotometer. The several fractions having significant optical density a t 260 mp were assayed for their radioactivity. Separation of Acid-Soluble Components.-For assay of amino acids and other carboxylic acids, the acidsoluble fraction from liver was neutralized with 1 N KOH and kept in a refrigerator overnight, and the precipitate of KC10, was centrifuged off. The neutralized supernatant was passed by gravity flow through Dowex 1 X10 (formate form, 200-400 mesh, 1 X 15 cm). The adsorbed substances were eluted by gradient elution with formic acid (Hurlbert et al., 1954). The fractions with high radioactivity were rechromatographed on Dowex 1 X10 with ammonium formate (Hurlbert et al., 1954) and then identified by paper chromatography. For the isolation of purine and pyrimidine compounds, the acid solution obtained as described above was heated in a boiling water bath for 1 hour and passed through an activated charcoala column, 1 x 5 cm (Tsuboj and Price, 1959). The column was washed with 15 ml of water and 15 ml of 0.01 N ammonia solution. The adsorbed substances were eluted with water-ethanol-concentrated NHsOH (2:2:1) and the eluate was dried under a stream of warm air. The residue was dissolved in 20 ml of water and the solution was run through a column of Dowex 1 XB (formate form, 200-400 mesh, 1 x 6 cm). The purine derivatives, hydrolyzed by the acid to adenine and guanine, and all pyrimidine derivatives, changed to their monophosphates, were successively eluted by water, by 0.01 M and 0.2 M formic acid, and finally by 0.01 0.075 M ammonium formate solution. Only UMP appeared in the last solution. Hydrolysis of UMP to Uracil.- -The UMP fractions isolated from the RNA or the acid-soluble fraction were dried a t 100". The residue was dissolved in a small amount of 12 M perchloric acid, quantitatively transferred to a glass test tube with a stopper, and heated in a boiling water bath for 1 hour (Marshak and Vogel, 1951). The hydrolyzed solution was diluted with 5 volumes of distilled water and the charcoal column treatmsnt was repeated. The eluted bases were dried, dissolved in sweral ml of water, and passed through a Dowex 50 X8 column ( H + form, 1 x 2 cm), which was then washed with 10 ml of water. The effluent and washings, containing the pure uracil derived from the UMP, were combined and decomposed as described below. Decomposition of Uracil.- -At first, uracil was decomposed by the method of Heinrich and Wilson (1950), except that the amount of the uracil in the sample was less (5 Fmoles) than used by them (200 pmoles). Uracil was decomposed to CO, and oxaluric acid by KMnOI in acid solution, and the Cor (Cor fraction) was absorbed in Hyamine solution. Then the oxaluric acid was decomposed by alkali to urea and oxalic acid and the latter was precipitated as calcium oxalate by addition of calcium chloride solution and removed by centrifugation from the supernatant, which contained the urea. However, when the amount of sample was very small, no precipitation occurred. In these cases,
+
+
+
3 Barneby-Cheney No. 1654 Activated Carbon, BarnebyCheney Co., Columbus 19, Ohio.
Biochemistry either 10 mg of nonradioactive uracil was added to the samples at the start, or 5-10 mg of oxalic acid was added just before this step. The precipitate of calcium oxalate was washed with a small amount of water, dissolved in 2 N sulfuric acid, and decomposed to COz by KMnO, (oxalic acid fraction). The supernatant solution and washings were combined, and urea was decomposed to COSand NH, by urease (urea fraction). Sine recovery of the radioactivity in the uracil by this procedure was only 60-85yo (Table 11),the method describedbelow was employed. I m p d Method.-Five ml of uracil-containing solution (5 m o l e ) was dried in a reaction flask and dissolved in 0.5 ml of water and 0.12 ml of 0.5 N sulfuric acid. The flask was connected with a glass U-tube to a Tricarb vial containing 1ml of Hyamine solution, and the sidearm of the flask was closed with a rubber serum bottle stopper (Sisken et al., 1961). Six-tenths ml of 0.4 N KMnO, was injected with a needle and syringe through the rubber stopper and the flask was shaken for 3 hours a t 37". After the reaction, the vial and flask were removed from the U-tube (Cot fraction). The contents of the flask were filtered and the flask was washed with hot water four times (each 0.5 ml). The filtrate and washings were colleded in another flask and 0.15 ml of 2 N NaOH was added; the solution was then heated in boiling water for 15 minutes. After cooling, 1 drop of phenolphthalein solution was added and the solution was neutralized with 1 N acetic acid. The addition was stopped while the color of the solution was still slightly pink. The flask was connected to a new vial and sealed as before, then 0.2 ml of a solution containing 0.3 mg urease per ml (Nutritional Biochemicals Corporation) in 0.1 Y Tris buffer, p H 8.0, was injected through the rubber stopper. During incubation a t 37", the flask was shaken, and after the second injection of urease (30 minutes later) the shaking was continued for more than 1 hour, after which 0.2 ml of 12 N sulfuric acid was injected. Again the vessel was shaken for 3 hours (urea fraction). A third vial containing 1ml of Hyamine was connected, and 1 ml of 0.4 N KMnO, was injected into the flask, which was shaken for 3 hours (oxalic acid fraction). These three vials were used for the determination of radioactivity.
RESULTSAND DISCUSSION Failure to Detect Carbamyl Phosphate Syntlletase Activity in Ehrlich Ascites Tumor Cells in vitm--Several types of cell preparations were examined for carbamyl phosphate synthetase activity, among them the following: the whole ascites fluid from Swiss mice 9 days after transplantation; a suspension of cells in Tris b d e r (pH 7.5, 0.1 M) after washing with 0.85% NaCl solution; the supernatant fluid obtained from ascites cek after homogenization in a Potter-Elvehjem homogenizer and centrifugation at O", 3000 rpm. Since carbamyl phosphate is very labile and there are no methods published by which to determine it directly, the following two methods were employed for detection of synthesis of this substance. (1)If carbamyl phosphate is synthesized and aspartic acid is present in the same reaction mixture, carbamyiaspartic acid should appear, since aspartic acid transcarbamylase activity is high in ascites tumor cells (Calva et al., 1959; Jones et QZ., 1961). Carbamyiaspartic acid was measured by the method of Koritz and Cohen (1954). (2) Active ornithine carbamyl transferase was prepared from rat liver (Grisolia, 1955) and this enzyme and ornithine were added to the reaction mixture. If carbamyl phosphate were synthesized, citrulline would be produced.
Vo1.2, No. 3, MayJune, 1963
CARBON DIOXIDE INCORPORATION INTO URACIL
575
TABLE I
INCORPORATION OF (31% samples Source
Time
In vitro Ascites cells
cpm/OD Unit.
INTO ~ a pRNA l OF ASCITES CELMAND LIVER
cpm/wmole in
UMP
-
CMP
AMP
GMP
521 (loo)< 807 (100)
8 (2) 121 (15)
90 (17) 143 (21)
33 (6) 102 (13)
178 (100) 546 (100) 258 (100)
75 (42) 334 (60) 266 (107)
81 (46) 356 (64) 228 (89)
53 (eo) 346 (62) 250 (97)
15 min. 30 min.
In uiuo Ascites cells
5 min. 15 min. 1 hr. 1hr.6 3 hr.b 6 hr. 48 hr. 6 hr. 48 hr.
Liver
1.1 35 130 18
50 226 206 1.9 1 5
a An optical density unit is de6ned as an absorbance of 1.0 in the 1-cm cell of the Beckman DU spectrophotometer at Figures in parentheses are the specific 260 mp. * 5 pc of NaHC"Oawas injected in these experiments, 25 pc in the others. activities relative to uracil. times 100.
Citrulline was measured by the method of Archibald (1944). The reaction solutions (5 ml, pH 7.5) contained: enzyme solution; 100 pmoles m c o a (or glutamine NaHC03, or (",)SO4 NaHC03); 20 pmoles ATP; 30 pnoles MgSO,; 10 pmoles acetylglutamic acid; and an ATP-regenerating system (phosphenolpyruvate phosphoenol pyruvate kinase). These mixtures were incubated for 15 or 30 minutes at 37" and HC10, was added to stop the reaction, after which the expected products were measured by the indicated methods. No carbamylaspartate or c i t d line formation was observed in any case. Hence, it may be concluded that carbamyl phosphate was not synthesized by ascites cells in vitro under our conditions. After this work was completed a similar finding was reported by Jonesetal. (1961). Incopmtion of C14 from NaHC1Q3 into RNA N w h t i d e s (TableI).-No radioactivity was detected in the RNA nucleotides in freshly removed Ehrlich ascites cells after 15 or 30 minutes' incubation of the whole ascites fluid (heparinized to prevent clotting) with NaHC103 (25 pc) in vitro. On the other hand, there was incorporation of C W Ointo n RNA even at 15 minutes in vim. The UMP moiety was labeled much more rapidly than the other nucleotides, and only 48 hours after the injection of the isotope did the specific activity of the other nucleotides approach that of UMP. In contrast, there was little detectable appearance of the label in liver RNA at the 6- and &hour intervals. Incopration of C' from NaHC1Q3 into Specific Positions of the Uracil of the Acid-Soluble Fmction and RNA.+ce our own experiment and those of others (Jones et al., 1961) failed to show carbamyl phosphate synthetase activity in vitro in Ehrlich tumors, it became of interest to see whether the C-2 atom of uracil can be derived to any extent from C 1 0 2 in vivo. The C-2 atom of uracil appears as COS after the final u r w treatment in our analytical procedure. The efficacy of that portion of the analytical method is demonstrated by the finding of 99% of the total radioactivity of synthetic ~racil-2-C'~ in this fraction and the recovery of 96-97% of t h z total radioactivity in the sample (Table 11). The (3-4, C-5, and C-6 atoms of uracil are estimated as the s u m of the Cot and oxalic acid fractions (Lagerkvist, 1953; Fairley et al., 1953). The adequacy of the modified procedure for these carbons is indicated by the generally good recoveries of the total radioactivity in the isolated samples of uracil (samples 6, 8-10, and 13-15 in Table 11). Results for
+
+
+
duplicate runs on the same sample also are shown (samples 9 and 10 and 14 and 15). There was only little incorporation of the C W , into the acid-soluble nucleotide fraction of the Ehrlich tumor cells in vitro. In the in vivo experiments incorporation of C W , took place into the C-2 of uracil, both in the acid-soluble fraction and in RNA, to a greater extent than into the other carbons, the radioactivity in this carbon accounting for approximately 90% of the total radioactivity found. In the uracil isolated from the acid-soluble nucleotide fraction of liver the C-2 contained only 49-70% of the total radioactivity, values similar to that in RNA of regenerating liver (Largerkvist, 1950). In the chromatography of extracts of livers of animals that had received NaHCW3,relatively high levels of radioactivity were noted in aspartic acid. The latter amino acid could Serve as a source of C-4, C-5, and C-6 of uracil, and therefore the proportion of the total radioactivity furnished by C-2 would be reduced. A smaller amount of label entering aspartate from the NaHCW3 in the tumor cells could account for the higher proportion of the isotope from this source being found in C-2 of the uracil in tumors. The rapid appearance of radioactivity in C-2 of the uracil of the RNA and of the soluble uracil pool in the tumor cells suggests that the C W 2 may enter rather directly into C-2 and is compatible with the existence of a carbamyl phosphate synthetase pathway in these animals. The simplest assumption which can be made about the discrepancy of the in vivo and in vitro results is that the methods to date employed for the in vitro work have failed to preserve and demonstrate the activiQ of an extremely sensitive enzyme. It is interesting in this connection that the carbamyl phosphate synthetase of intestine is much more labile than that of liver (Hall et al., 1960). It may also be that some other mechanism, similar to that for the synthetase but requiring other conditions for demonstration, is involved in the CO, fixation. Another possibility is that the carbamyl phosphate may be made in the liver, the tissue with by far the highest synthetase activity, and transported in some form to the tumor cells and other tissues vicr the blood stream. The much smaller incorporation of C1*02into uracil in a short Z R vitro experiment with whole tumor (sample 6, Table 11) and the smaller proportion of total radioactivity found in C-2 of uracil than in a comparable in vivo experiment (sample8, Table 11)is consistent with such a possibility. The high aspartate transcarbamylase levels in Ehrlich tumors (Calva et al., 1959; Jones et al., 1961) together
576
Biochemi&y
ICEIICHI EXJSAMA AND EUGENE ROBERTS
TABLE I1 DISIWBLTXON OF C14 IN TBE UBACIL MOLECULE c-2 C-4,5,6 Sample No. 1.
Description
3 46
Synthetic uracil2-c 14 Same Same Same
5=
Same
2
C-2
x
100
+ C-4 + C-5 +
Urea (cpm)
C-6
Recovery of C14in Sample
(%)
( %)
36.8
8977
99
96
20.2 27.2 40.4 31.0
38.8 24.6 30.0 16.6
8974 9128
99 99
96 97
99 99
80
17
7.0
2.6
6.0
38
92
15 min.
17
4.0
4.2
4.8
37
76
5 min.
500
35.4
3.2
367
90
81
6 hr. 6 hr. 6 hr. 3 hr. 6 hr. 5 min.
293 293 293
22.0 22.6 18.6 16.0 2.4 66.0
8.4 6.2 11.2 3.6 6.0 23.8
263
90 90 85 88 87 52
100 97 67 63 91 96
5 min. 6 hr. 6 hr.
175 247
64.8 61.8 58.0
24.0 15.2 41.2
89 182 66
49
104 104 67
Total Activity (cpm)
C02 (cpm)
oxalic Acid (cpm)
9464
13.8
9464 9464 9464 9464 15 min.
Time
-
8018
7539
C-2
84
In vitro 6 7b
ABcites cells, acidsoluble fraction Same
In vim 8 9 10 1 1 b
12b 13 14
-
15 16 17b
Ascites cells, acid-
soluble nucleotide fraction Same Same Same Ascites cells, RNA Same Liver, acid-soluble fraction Same Same Same
270
70 194
247
257 166 159 55 96
70
40
Precipitation achieved by addition of unlabeled oxalic Purchased from Isotope Specialties Co., Inc., 0.6 mc/rma. acid. Method of Heinrich and Wilson (1950). c Addition of unlabeled uracil. Method of Heinrich and Wilson (1950).
with the results of the present work are strongly suggestive of the existence of the orotic acid pathway of pyrimidine biosynthesis in these tumor cells. The Ehrlich tumor also high levels of uridine phosphoryhe and u n h kmase, enabling the tumor to make U M P directly from uracil (Reichard, 1959). However, it does not appear likely from our results that uracil formed in the liver is a direct precursor of most of the uracil in the tumor cells, since the proportion of total radioactivi@ in the C-2 is so much higher in the uracil of the tumors. Label from NaHC'Q, is incorporated into the RNA and DNA of cancer cells in tissue culture (McCoy et aZ., 1961; Chang et d.,1961). From the fact that C"OZalso is incorporated into aspartate (McCoy et al., 1961)and oxalacetate (Chang et aZ., 1961),it is possible that C'Qo, might Grst be nicom& rd into aspartic acid, as in liver, after which the carbamyl moiety from citrulline might be transferred to make carbamyl a s partic acid (Smith and Reichard, 1956; Reichard, 1957), which would then be incorporated into RNA UM the orotic pathway. At the present time it is not possible to compare our r d t s with those obtained under tissue culture conditions employing difFerent tumor cell lines.
REPERENCEW Archibald, R. M. (1944), J. B i d . Chem. 156, 121. Calva, E., Lowenstein, J. M., and Cohen, P. P. (1959), Cancer Res. 19, 101. Chang, R. S., Liepins, H., and Margolish, M. (1961), Proc. Soc. Exp. B i d . Med. Im, 149. Cohn, W. E., and Volkin, E. (1951), Nature 167,483.
Fairley, J. L., Dans, L. L., and Krueckel, B. (1953), J. Am. Chem. Soc. 75,3842. Grisolia, S. (1955), Methods in E m y d . 2, 350. Hall, L. M., Johnson, R. C., and Cohen, P. P. (1960), Biochirn. Bwphys. Acta 37, 144. Heinrich, M. R., and Wilson, D. W. (1950), J. B i d . Chem. 186,447. Hurlbert, R. B., Schmitz, H., Brumm, A. F., and Potter, V. R. (1954), J . B i d . Chem.209,23. Jones, M. E., Anderson, A. D., Anderson, C., and H o d s , S. (1961),Arch. Biochem. Biophys. 95,499. Koritz, S. B., and Cohen, P. P. (1954), J . B i d . Chern. 209, 145. Lagerkvist, U. (1950), Acta Chem. scand. 4, 1151. Lagerkvist, U. (1953), Acto Chem. scand. 7, 114. McCoy, T. A., Maxwell, M. D., and Kruse, P. F., Jr. (1961). cancer Res. 21, 997. Marshak, A., and Vogel, H. J. (1951), J . B i d . Chem. 189, 597. Reichard, P. (1957), Acta Chem. scand. 11, 523. Reichard, P. (1959), in Proc. IVth Internat. Congr. Biochem., Vienna, 1958, Vol. XIII, Hoffmann-Ostenhof, O., Editor, Pergamon Press, p. 119. Reichard, P., and Lagerkvist, U. (1953), Acta Chem. Scad. 7, 1207. Reichard, P., and Skold, 0. (1957), Acta Chem. Scad. 11, 17. Sisken, B., Sano, K., and Roberts, E. (1961), J. Biol. Chem. 236,503. Skold, 0. (1960).Biochem. Biophys. Acta 44,1. Smith, L. H., Jr., and Reichard, P. (1956), Acta Chem. Scad. 10, 1024. Tsuboi, K. K.,and Price, T. D. (1959), Arch. B k h e m . Biophys. 81, 223. Tyner, E. P., Heidelberg-, C., and LePage, G. A. (1953), Cancer Res. 13.186.